Summary
The first physical contact between the embryo and the uterus is a complex and timely coordinated process, which is crucial for positive pregnancy outcome. During that process of implantation, the embryo attaches and invades to nest into the uterus. Managing embryo implantation has wide implications for public health, including treating infertility (e.g., improving IVF outcomes) and for family planning (improving contraception). However, the tiny size of the embryo and inaccessibility into the womb make implantation a true black box in developmental biology. Three technological breakthroughs, i.e., single cell sequencing, endometrial organoids and blastoid technologies, now made it possible to deeply and finely investigate implantation. Here, I aim at leveraging these technologies to create a stem cell-based platform to model the blastocyst-uterus interaction and to reveal molecular mechanisms mediating implantation. This platform will be amenable to high-throughput screening, gene editing, and live imaging, to identify the molecular regulators of implantation. If successful, this study will provide a biologically relevant, easily accessible and experimentally amenable system to perform in-depth studies with scientific and clinical impacts to understand and potentially treat conditions such as infertility, reproductive decline, develop novel contraceptive and in the long term, to develop drugs to improve reproductive health and prevent several chronic diseases.
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| Web resources: | https://cordis.europa.eu/project/id/101026451 |
| Start date: | 01-09-2022 |
| End date: | 31-08-2024 |
| Total budget - Public funding: | 174 167,04 Euro - 174 167,00 Euro |
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Original description
The first physical contact between the embryo and the uterus is a complex and timely coordinated process, which is crucial for positive pregnancy outcome. During that process of implantation, the embryo attaches and invades to nest into the uterus. Managing embryo implantation has wide implications for public health, including treating infertility (e.g., improving IVF outcomes) and for family planning (improving contraception). However, the tiny size of the embryo and inaccessibility into the womb make implantation a true black box in developmental biology. Three technological breakthroughs, i.e., single cell sequencing, endometrial organoids and blastoid technologies, now made it possible to deeply and finely investigate implantation. Here, I aim at leveraging these technologies to create a stem cell-based platform to model the blastocyst-uterus interaction and to reveal molecular mechanisms mediating implantation. This platform will be amenable to high-throughput screening, gene editing, and live imaging, to identify the molecular regulators of implantation. If successful, this study will provide a biologically relevant, easily accessible and experimentally amenable system to perform in-depth studies with scientific and clinical impacts to understand and potentially treat conditions such as infertility, reproductive decline, develop novel contraceptive and in the long term, to develop drugs to improve reproductive health and prevent several chronic diseases.Status
SIGNEDCall topic
MSCA-IF-2020Update Date
28-04-2024
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